Wheat having reduced waxy protein due to non-transgenic alterations of a waxy gene

ABSTRACT

A series of independent non-transgenic mutations found at the waxy loci of wheat; wheat plants having these mutations in their waxy loci; and a method of creating and finding similar and/or additional mutations of the waxy by screening pooled and/or individual wheat plants. The wheat plants of the present invention exhibiting altered waxy activity in the wheat without having the inclusion of foreign nucleic acids in their genomes. The invention also includes food and non-food products as well as non-food products that incorporate seeds from the wheat plants having non-transgenic mutations in one or more waxy genes.

The present application claims benefit to U.S. Provisional Application No. 60/526,678, filed on 3 Dec. 2003; U.S. Provisional Application No. 60/571,432, filed on 14 May 2004; and U.S. Provisional Application No. 60/620,708, filed on 19 Oct. 2004. The entire contents of each of these applications are incorporated by reference herein in their entirety.

FIELD OF THE INVENTION

This invention concerns non-transgenic mutations at one or more waxy locus of wheat and wheat plants having these non-transgenic mutations in their waxy sequences. This invention further concerns wheat plants having starch with lower amylose and higher amylopectin levels compared to starch from wild type wheat as a result of non-transgenic mutations in at least one of their waxy genes. This invention also concerns a method that utilizes non-transgenic means to create wheat plants having mutations in their waxy genes.

BACKGROUND

The ratio of amylose to amylopectin in starch significantly affects the characteristics and quality of its finished food products including their digestibility, water retention, and resistance to staling. Starches that are high in amylose, a linear polymer, tend to gel when cooked whereas those that are high in amylopectin, a branching polymer, tend to form viscous pastes. Because of their unique physical properties including their pasting properties, solubility, gelling capacity, gel strength, swelling power, and vicosity, low amylose/high amylopectin starches are often used in the food industry to improve the texture and mouth-feel of select food products as well as their freeze-thaw stability.

Amylose synthesis in a variety of plants, including wheat, is regulated for the most part by the enzyme granule-bound starch synthase (GBSSI), also known as waxy protein. The importance of this gene in starch synthesis has been well documented in naturally occurring varieties of GBSSI-deficient rice and corn, termed waxy mutants. Following the commercialization of waxy rice and waxy corn starches, there has been extensive interest by wheat breeders and the U.S. Department of Agriculture to develop waxy wheat lines for use in the food industry as well as other commercial applications. Whereas starch from most traditional wheat cultivars is approximately 24% amylose and 76% amylopectin, starch from full waxy wheat lines (i.e., carrying deletions of all three genes) is almost 100% amylopectin. Potential commercial uses of waxy wheat starch include its use as a sauce thickener, emulsifier, and shelf-life extender. When mixed with traditional wheat flour in bread dough, waxy wheat flour improves crumb texture, freshness, and softness and eliminates the need for shortenings, thereby reducing fat content, unhealthy trans-fatty acids, and cost. Blended with other regular flours, waxy wheat flour improves the texture and tenderness of pasta and noodles, including Japanese udon noodles. In addition to the food industry, high amylopectin starches are important to the paper industry for enhancing the strength and printing properties of paper products and to the adhesive industry as a component of glues and adhesives, especially those used on bottles.

Though breeding programs are underway to develop commercial varieties of waxy wheat, the polyploid nature of the wheat genome combined with homoeologous chromosome pairing has made the identification of waxy wheat mutants through traditional breeding methods difficult. The majority of wheat traded in commerce is Triticum aestivum or bread wheat. In this hexaploid, waxy is encoded by three homoeologues, Wx-7A, Wx-4A, and Wx-7D with the chromosomal locations 7AS, 4AL, and 7DS (Murai et al., Isolation and characterization of the three Waxy genes encoding the granule-bound starch synthase in hexaploid wheat. Gene 234: 71-79, 1999). In order to breed full waxy varieties using traditional breeding methods, knock-out mutations of all three homoeologues are required. Although several hundred lines of wheat have been identified that carry one or more mutations in the waxy genes Wx-4A and Wx-7A, only four deletion mutations of Wx-7D have been identified to date in over three thousand wheat lines that have been evaluated. One of these is in a Chinese landrace called Bai Huo, whose genetic heterogeneity makes it less suitable for traditional wheat breeding programs than modern elite cultivars. A cross between a double waxy null, Kanto 107, and the Bai Huo landrace was performed to create the first full waxy null line in wheat (Nakamura et al., Mol Gen Genet 248: 253-259, 1995). Despite the recent development of waxy breeding lines using this starting material, commercial varieties of waxy wheat are still not available, presumably due to the difficulty of removing undesirable agronomic traits from exotic germplasm. The paucity of Wx-7D deletion mutations has severely limited the development of commercial waxy wheat lines through traditional breeding.

With the availability of the genetic sequences of the Triticum aestivum waxy genes, transgenic technology could be used to modify the expression of targeted proteins like waxy rather than rely on traditional breeding programs for the development of waxy wheat cultivars which could take years. However, public acceptance of genetically modified plants, particularly with respect to plants used for food, is low. Therefore, it would be useful to have additional commercial varieties of full or partial waxy wheat that were not the result of genetic engineering. The availability of multiple allelic mutations within each waxy locus would also allow for the breeding of new, diverse waxy phenotypes showing a spectrum of functional characteristics.

SUMMARY OF THE INVENTION

In one aspect, this invention includes a wheat plant having reduced waxy enzyme activity compared to wild type wheat plants created by the steps of obtaining plant material from a parent wheat plant, inducing at least one mutation in at least one copy of a waxy gene of the plant material by treating the plant material with a mutagen to create mutagenized plant material, culturing the mutagenized plant material to produce progeny wheat plants, analyzing progeny wheat plants to detect at least one mutation in at least one copy of a waxy gene, selecting progeny wheat plants that have reduced waxy enzyme activity compared to the parent wheat plant; and repeating the cycle of culturing the progeny wheat plants to produce additional progeny plants having reduced waxy enzyme activity. In another aspect, this invention includes a wheat plant, flowers, seeds, plant parts, and progeny thereof having reduced waxy enzyme activity compared to the wild type wheat plants wherein the reduced waxy enzyme activity is caused by a non-transgenic mutation in a waxy gene of the wheat plant. In another aspect, this invention includes a plant containing a mutated waxy gene, as well as flowers, seeds, pollen, plant parts and progeny of that plant. In another aspect, this invention includes food and food products as well as non-food products that incorporate starch from wheat plants having reduced waxy enzyme activity caused by a non-transgenic mutation in the waxy gene.

BRIEF DESCRIPTION OF THE SEQUENCE LISTING

-   SEQ ID NO: 1 shows the Triticum aestivum gene for starch synthase     (waxy), complete cds. (GenBank Accession Number AB019623). This     sequence corresponds to the waxy gene Wx-4A. -   SEQ ID NO: 2 shows the protein encoded by SEQ ID NO: 1 (GenBank     Accession Number BAA77351). -   SEQ ID NO: 3 shows the Triticum aestivum gene for starch synthase     (waxy), complete cds. (GenBank Accession Number AB019622). This     sequence corresponds to the waxy gene Wx-7A. -   SEQ ID NO: 4 shows the protein encoded by SEQ ID NO: 3 (GenBank     Accession Number BAA77350). -   SEQ ID NO: 5 shows the Triticum aestivum gene for starch synthase     (waxy), complete cds. (GenBank Accession Number AB019624). This     sequence corresponds to the waxy gene Wx-7D. -   SEQ ID NO: 6 shows the protein encoded by SEQ ID NO: 5 (GenBank     Accession Number BAA77352). -   SEQ ID NO: 7-20 show the DNA sequences for the starch synthase     (waxy) specific primers of the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The present invention describes a series of independent non-transgenic mutations in a waxy gene; wheat plants having these mutations in a waxy gene thereof; and a method of creating and identifying similar and/or additional mutations in a waxy gene of wheat. Additionally, the present invention describes wheat plants created by this method having low amylose/high amylopectin starch without the inclusion of foreign nucleic acids in the plants' genomes.

In order to create and identify the waxy mutations and the wheat plants of the present invention, a method known as TILLING® was utilized. See McCallum et al., Nature Biotechnology, 18: 455-457, 2000; McCallum et al., Plant Physiology, 123: 439-442, 2000; Colbert et al., Plant Physiol. 126(2): 480-484, 2001 and U.S. Pat. No. 5,994,075 and 20040053236, all of which are incorporated herein by reference. In the basic TILLING® methodology, plant material, such as seeds, are subjected to chemical mutagenesis, which creates a series of mutations within the genomes of the seeds' cells. The mutagenized seeds are grown into adult M1 plants and self-pollinated. DNA samples from the resulting M2 plants are pooled and are then screened for mutations in a gene of interest. Once a mutation is identified in a gene of interest, the seeds of the M2 plant carrying that mutation are grown into adult M3 plants and screened for the phenotypic characteristics associated with the gene of interest.

For the present invention the hexaploid cultivar Express (a hexaploid variety that naturally lacks the 4A locus) and the tetraploid cultivar Kronos were used. However, any cultivar of wheat having at least one waxy gene with substantial homology to SEQ ID NO: 1, SEQ ID NO: 3, or SEQ ID NO: 5 may be used. The homology between the waxy genes and SEQ ID NO: 1, SEQ ID NO: 3, or SEQ ID NO: 5 may be as low as 60% provided that the homology in the conserved regions of the gene is higher. One of skill in the art may prefer a wheat cultivar having commercial popularity or one having specific desired characteristics in which to create the waxy-mutated wheat plants. Alternatively, one of skill in the art may prefer a wheat cultivar having few polymorphisms, such as an in-bred cultivar, in order to facilitate screening for mutations within the waxy locus.

In one embodiment of the present invention, seeds from wheat plants were mutagenized and then grown into M1 plants. The M1 plants were then allowed to self-pollinate and seeds from the M1 plant were grown into M2 plants, which were then screened for mutations in their waxy loci. An advantage of screening the M2 plants is that all somatic mutations correspond to the germline mutations. One of skill in the art would understand that a variety of wheat plant materials, including but not limited to seeds, pollen, plant tissue or plant cells, may be mutagenized in order to create the waxy-mutated wheat plants of the present invention. However, the type of plant material mutagenized may affect when the plant DNA is screened for mutations. For example, when pollen is subjected to mutagenesis prior to pollination of a non-mutagenized plant, the seeds resulting from that pollination are grown into M1 plants. Every cell of the M1 plants will contain mutations created in the pollen, thus these M1 plants may then be screened for waxy mutations instead of waiting until the M2 generation.

Mutagens that create primarily point mutations and short deletions, insertions, transversions, and or transitions (about 1 to about 5 nucleotides), such as chemical mutagens or radiation, may be used to create the mutations of the present invention. Mutagens conforming with the method of the present invention include, but are not limited to, ethyl methanesulfonate (EMS), methylmethane sulfonate (MMS), N-ethyl-N-nitrosurea (ENU), triethylmelamine (TEM), N-methyl-N-nitrosourea (MNU), procarbazine, chlorambucil, cyclophosphamide, diethyl sulfate, acrylamide monomer, melphalan, nitrogen mustard, vincristine, dimethylnitosamine, N-methyl-N′-nitro-Nitrosoguanidine (MNNG), nitrosoguanidine, 2-aminopurine, 7, 12 dimethyl-benz(a)anthracene (DMBA), ethylene oxide, hexamethylphosphoramide, bisulfan, diepoxyalkanes (diepoxyoctane (DEO), diepoxybutane (BEB), and the like), 2-methoxy-6-chloro-9[3-(ethyl-2-chloro-ethyl)aminopropylamino] acridine dihydrochloride (ICR-170), and formaldehyde. Spontaneous mutations in a waxy gene that may not have been directly caused by the mutagen can also be identified using the present invention.

Any method of plant DNA preparation known to those of skill in the art may be used to prepare the wheat plant DNA for waxy mutation screening. For example, see Chen & Ronald, Plant Molecular Biology Reporter 17: 53-57 (1999); Stewart & Via, Bio Techniques, 1993, 14: 748-749. Additionally, several commercial kits are available, including kits from Qiagen (Valencia, Calif.) and Qbiogene (Carlsbad, Calif.).

Prepared DNA from individual wheat plants was then pooled in order to expedite screening for mutations in a waxy gene of the entire population of plants originating from the mutagenized plant tissue. The size of the pooled group is dependent upon the sensitivity of the screening method used. Preferably, groups of two or more individuals are pooled.

After the DNA samples were pooled, the pools were subjected to waxy sequence-specific amplification techniques, such as Polymerase Chain Reaction (PCR). For a general overview of PCR, see PCR Protocols: A Guide to Methods and Applications (Inns, M., Gelfand, D., Sninsky, J., and White, T., eds.), Academic Press, San Diego (1990). Any primers specific to the waxy loci or the sequences immediately adjacent to the waxy loci may be utilized to amplify the waxy sequences within the pooled DNA sample. Preferably, the primer is designed to amplify the regions of the waxy loci where useful mutations are most likely to arise. Most preferably, the primer is designed to detect exonic regions of the waxy genes. Additionally, it is preferable for the primer to avoid known polymorphic sites in order to ease screening for point mutations. To facilitate detection of PCR products on a gel, the PCR primer may be labeled using any conventional labeling method. In the present invention, primers were designed based upon the waxy sequences, GenBank accession numbers AB019623 (SEQ ID NO: 1), AB019622 (SEQ ID NO: 3), and AB019624 (SEQ ID NO: 5). Exemplary primers (SEQ ID NOs: 7-20) that have proven useful in identifying useful mutations within the waxy sequences are shown below in Table 1.

SEQ ID NO NAME ID SEQUENCE 7 7A WX 2L PR-1042 ACCCGCATGGTGTTTGATAATTTCAGTG 8 7A WX 2R PR-1043 AGAATGCCACCTAGCCATGAAATGGAGT 9 7A WX 3L PR-1045 CGCTCTGCATATCAATTTTGCGGTTC 10 7A WX 3R PR-1046 CCTGCAATGCATTCGATCAGTCAGTC 11 7A WX 4L PR-1048 GTTCTCCTGGTACGATCGACCGACATT 12 7A WX 4R PR-1049 ATCGGCCCTTCACTCTTAGTTGTTCCAG 13 7D WX 2L PR-1039 TCGTCGTCTCAACCTTGATAGGCATGGTGAT 14 7D WX 2R PR-1040 GAACCGCAAAATTGATATGCCTGTTTCA 15 7D WX 3L PR-0973 TGAAACAGGCATATCAATTTTGCGGTTC 16 7D WX 3R PR-0974 TCGATCATTCCTTAGGTCTGCTTGATCG 17 4A WX 8L PR-1426 CCACCCACACACCCACACAAAGAT 18 4A WX 8R PR-1428 TTTACACAAGGGATCGACGAGCCTAC 19 4A WX 6L PR-1369 GGTAAGATCAACAACACCCAGCAGCTA 20 4A WX 3R PR-1306 AACCAGCAATCACCGGAAGAAATCTTTG

The PCR amplification products may be screened for waxy mutations using any method that identifies nucleotide differences between wild type and mutant sequences. These may include, for example but not limited to, sequencing, denaturing high pressure liquid chromatography (dHPLC), constant denaturant capillary electrophoresis (CDCE), temperature gradient capillary electrophoresis (TGCE) (Li et al., Electrophoresis, 23(10): 1499-1511, 2002, or by fragmentation using enzymatic cleavage, such as used in the high throughput method described by Colbert et al., Plant Physiology, 126: 480-484, 2001. Preferably the PCR amplification products are incubated with an endonuclease that preferentially cleaves mismatches in heteroduplexes between wild type and mutant sequences. Cleavage products are electrophoresed using an automated sequencing gel apparatus, and gel images are analyzed with the aid of a standard commercial image-processing program.

Each mutation is evaluated in order to predict its impact on protein function (i.e., completely tolerated to loss-of-function) using biofinormatics tools such as SIFT (Sorting Intolerant from Tolerant; Ng and Henikoff, Nuc Acids Res 31: 3812-3814, 2003), PSSM (Position-Specific Scoring Matrix; Henikoff and Henikoff, Comput Appl Biosci 12: 135-143, 1996) and PARSESNP (Taylor and Greene, Nuc Acids Res 31: 3808-3811, 2003). For example, a SIFT score that is less than 0.05 and a large change in PSSM score (roughly 10 or above) indicate a mutation that is likely to have a deleterious effect on protein function.

Mutations that reduce waxy protein function are desirable. Because of the diverse ways in which wheat starch is used, an allelic series of mutations that result in a spectrum of functional characteristics would be useful. Preferred mutations include missense, splice junction, and nonsense changes including mutations that prematurely truncate the translation of the waxy protein from messenger RNA, such as those mutations that create a stop codon within the coding region of the waxy gene. These mutations include insertions, repeat sequences, modified open reading frames (ORFs) and, most preferably, point mutations.

Once an M2 plant having a mutated waxy sequence is identified, the mutations are analyzed to determine its affect on the expression, translation, and/or activity of the waxy enzyme. First, the PCR fragment containing the mutation is sequenced, using standard sequencing techniques, in order to determine the exact location of the mutation in relation to the overall waxy sequence.

If the initial assessment of the mutation in the M2 plant appears to be of a useful nature and in a useful position within the waxy sequence, then further phenotypic analysis of the wheat plant containing that mutation is pursued. First, the M2 plant is backcrossed or outcrossed twice in order to eliminate background mutations. Then the backcrossed or outcrossed plant is self-pollinated in order to create a plant that is homozygous for the waxy mutation. Waxy mutant plants are assessed to determine if the mutation results in a useful phenotypic change including starch type and content, starch characteristics, and seed opaqueness (for example, see Fujita et al., Plant Science, 160: 595-602, 2001).

The following mutations in Tables 2 are exemplary of the mutations created and identified according to the present invention. They are offered by way of illustration, not limitation.

Table 2: Examples of Mutations Created and Identified in the Wx-4A, Wx-7A and Wx-7D Waxy Homoeologs of Wheat.

TABLE 2 Amino Nucleotide Acid Numbered Numbered Primer Amino According According Type of WAXY SEQ EMS Nucleotide Acid to SEQ ID to SEQ ID Mutation Variety Gene IDs. Treatment Mutation Mutation NO: NO: Truncation Express 7A  7 and 8 0.75% C852T Q189* 3 4 Truncation Express 7D 13 and 0.75% C890T Q197* 5 6 14 Truncation Kronos 7A  9 and 0.075%  G1572A W354* 3 4 10 Missense Kronos 4A 19 and 0.075%  G1115A V224M 1 2 20 Missense Kronos 4A 19 and 0.075%  C1140T T232M 1 2 20 Missense Kronos 4A 17 and 0.075%  G1993A G434E 1 2 18 Missense Kronos 4A 17 and 0.075%  C2040T P450S 1 2 18 Missense Kronos 4A 17 and 0.075%  G2053A R454K 1 2 18 Missense Kronos 4A 17 and 0.075%  C2154T L488F 1 2 18 Missense Kronos 4A 17 and 0.075%  G2161A G490E 1 2 18 Missense Express 7A  7 and 8 0.75% G832A G182D 3 4 Missense Express 7A  7 and 8 0.75% C858T R191C 3 4 Missense Express 7A  7 and 8 0.75% G882A A199T 3 4 Missense Express 7A  7 and 8 0.75% C922T P212L 3 4 Missense Express 7A  7 and 8 1.00% G1070A E220K 3 4 Missense Express 7A  7 and 8 1.00% G1107A G232D 3 4 Missense Express 7A  7 and 8 0.75% C1116T A235V 3 4 Missense Express 7A  7 and 8 0.75% C1143T S244F 3 4 Missense Express 7A  9 and 0.75% G1425A G305E 3 4 10 Missense Express 7A  9 and 1.00% G1533A G341E 3 4 10 Missense Express 7A  9 and 0.75% G1542A G344D 3 4 10 Missense Express 7A  9 and 0.75% G1586A D359N 3 4 10 Missense Express 7A  9 and 0.75% C1595T L362F 3 4 10 Missense Express 7A  9 and 0.75% C1599T T363I 3 4 10 Missense Express 7A  9 and 0.75% G1761A G387R 3 4 10 Missense Express 7A  9 and 1.00% G1770A V390M 3 4 10 Missense Express 7A  9 and 0.75% C1851T P417S 3 4 10 Missense Express 7A 11 and 0.75% G1995A G433E 3 4 12 Missense Express 7A 11 and 1.00% C2042T P449S 3 4 12 Missense Express 7A 11 and 0.75% G2060A V455M 3 4 12 Missense Express 7A 11 and 0.75% C2100T A468V 3 4 12 Missense Express 7A 11 and 0.75% G2103A G469D 3 4 12 Missense Express 7A 11 and 0.75% G2274A C496Y 3 4 12 Missense Express 7A 11 and 0.75% C2283T A499V 3 4 12 Missense Express 7A 11 and 0.75% G2292A G502D 3 4 12 Missense Express 7A 11 and 1.00% G2315A E510K 3 4 12 Missense Kronos 7A  9 and 0.075%  G1469A A320T 3 4 10 Missense Kronos 7A  9 and 0.075%  C1485T S325F 3 4 10 Missense Kronos 7A  9 and 0.075%  G1490A E327K 3 4 10 Missense Kronos 7A 11 and 0.075%  C2042T P449S 3 4 12 Missense Kronos 7A 11 and 0.075%  C2129T R478C 3 4 12 Missense Kronos 7A 11 and 0.075%  G2162A G489R 3 4 12 Missense Express 7D 13 and 1.00% G860T D187Y 5 6 14 Missense Express 7D 13 and 0.75% G879A S193N 5 6 14 Missense Express 7D 13 and 1.00% G896A A199T 5 6 14 Missense Express 7D 13 and 1.00% G1109A G219E 5 6 14 Missense Express 7D 13 and 0.75% G1130A C226Y 5 6 14 Missense Express 7D 13 and 0.75% G1147A G232S 5 6 14 Missense Express 7D 13 and 1.00% G1148A G232D 5 6 14 Missense Express 7D 13 and 0.75% G1160A C236Y 5 6 14 Missense Express 7D 13 and 0.75% C1184T S244F 5 6 14 Missense Express 7D 15 and 1.00% G1351A V253M 5 6 16 Missense Express 7D 15 and 0.75% C1424T P277L 5 6 16 Missense Express 7D 15 and 0.75% G1507A G305R 5 6 16 Missense Express 7D 15 and 0.75% G1528A V312M 5 6 16 Missense Express 7D 15 and 0.75% C1535T T314M 5 6 16 Missense Express 7D 15 and 0.75% G1558A E322K 5 6 16 Missense Express 7D 15 and 0.75% C1622T T343I 5 6 16 Missense Express 7D 15 and 0.75% G1625A G344D 5 6 16 Missense Express 7D 15 and 0.75% G1630A V346I 5 6 16 Missense Express 7D 15 and 0.75% C1661T P356L 5 6 16 Missense Express 7D 15 and 0.75% C1682T A363V 5 6 16 Missense Express 7D 15 and 0.75% C1682T A363V 5 6 16 Missense Express 7D 15 and 1.00% C1844T P389S 5 6 16 Missense Express 7D 15 and 1.00% C1905T P409L 5 6 16 Missense Express 7D 15 and 0.75% G1907A D410N 5 6 16 Splice Express 7A 11 and 0.75% G2180A Splice 3 4 Junction 12 Splice Express 7A 11 and 1.00% G2180A Splice 3 4 Junction 12 Splice Express 7D 13 and 1.00% G957A Splice 5 6 Junction 14 Splice Express 7D 13 and 0.75% G1108A Splice 5 6 Junction 14 Splice Express 7D 15 and 0.75% G1970A Splice 5 6 Junction 16

EXAMPLE 1 Mutagenesis

In one embodiment of the present invention, wheat seeds of the hexaploid cultivar (Triticum aestivum) Express and the tetrapolid cultivar (Triticum turgidum, Durum) Kronos were vacuum infiltrated in H₂O (approximately 1000 seeds/100 ml H₂O for approximately 4 minutes). The seeds were then placed on a shaker (45 rpm) in a fume hood at ambient temperature. The mutagen ethyl methanesulfonate (EMS) was added to the imbibing seeds to final concentrations ranging from about 0.75% to about 1.2% (v/v). Following an 18-hour incubation period, the EMS solution was replaced with fresh H₂O (4 times). The seeds were then rinsed under running water for about 4-8 hours. Finally, the mutagenized seeds were planted (96/tray) in potting soil and allowed to germinate indoors. Plants that were four to six weeks old were transferred to the field to grow to fully mature M1 plants. The mature M1 plants were allowed to self-pollinate and then seeds from the M1 plant were collected and planted to produce M2 plants.

DNA Preparation

DNA from these M2 plants was extracted and prepared in order to identify which M2 plants carried a mutation at their waxy loci. The M2 plant DNA was prepared using the methods and reagents contained in the Qiagen® (Valencia, Calif.) DNeasy® 96 Plant Kit. Approximately 50 mg of frozen plant sample was placed in a sample tube with a tungsten bead, frozen in liquid nitrogen and ground 2 times for 1 minute each at 20 Hz using the Retsch® Mixer Mill MM 300. Next 400 μl of solution AP1 [Buffer AP 1, solution DX and RNAse (100 mg/ml)] at 80° C. was added to the sample. The tube was sealed and shaken for 15 seconds. Following the addition of 130 μl Buffer AP2, the tube was shaken for 15 seconds. The samples were placed in a freezer at minus 20° C. for at least 1 hour. The samples were then centrifuged for 20 minutes at 5600×g. A 400 μl aliquot of supernatant was transferred to another sample tube. Following the addition of 600 μl of Buffer AP3/E, this sample tube was capped and shaken for 15 seconds. A filter plate was placed on a square well block and 1 ml of the sample solution was applied to each well and the plate was sealed. The plate and block were centrifuged for 4 minutes at 5600×g. Next, 800 μl of Buffer AW was added to each well of the filter plate, sealed and spun for 15 minutes at 5600×g in the square well block. The filter plate was then placed on a new set of sample tubes and 80 μl of Buffer AE was applied to the filter. It was capped and incubated at room temperature for 1 minute and then spun for 2 minutes at 5600×g. This step was repeated with an additional 80 μl Buffer AE. The filter plate was removed and the tubes containing the pooled filtrates were capped. The individual samples were then normalized to a DNA concentration of 5 to 10 ng/μl.

Tilling®

The M2 DNA was pooled into groups of two individual plants. The DNA concentration for each individual within the pool was approximately 0.8 ng/μl with a final concentration of 1.6 ng/μl for the entire pool. Then, 5 μl of the pooled DNA samples 8 ng was arrayed on microtiter plates and subjected to gene-specific PCR.

PCR amplification was performed in 15 μl volumes containing 2.5 ng pooled DNA, 0.75×ExTaq buffer (Panvera®, Madison, Wis.), 2.6 mM MgCl₂, 0.3 mM dNTPs, 0.3 μM primers, and 0.05U Ex-Taq (Panvera®) DNA polymerase. PCR amplification was performed using an MJ Research® thermal cycler as follows: heat denaturation at 95° C. for 2 minutes; followed by 8 cycles of “touchdown PCR” (94° C. for 20 second, an annealing step starting at 70-68° C. for 30 seconds and decreasing 1° C. per cycle, a temperature ramp increasing 0.5° C. per second to 72° C., and 72° C. for 1 minute); then 25-45 cycles of PCR (94° C. for 20 seconds, 63-61° C. for 30 seconds, ramp of 0.5° C. per second up to 72° C., 72° C. for 1 minute); and finally extension, denaturation and reannealing steps (72° C. for 8 minutes; 98° C. for 8 minutes; 80° C. for 20 seconds, followed by 60 cycles of 80° C. for 7 seconds decreasing 0.3 degrees/cycle).

The PCR primers (MWG Biotech, Inc., High Point, N.C.) were mixed as follows:

2.5 μl 100 μM IRD-700 labeled left primer

7.5 μl 100 μM left primer

9.0 μl 100 μM IRD-800 labeled right primer

1.0 μl 100 μM right primer

A label can be attached to each primer as described or to only one of the primers. Alternatively, Cy5.5 modified primers could be used. The IRD-label was coupled to the oligonucleotide using conventional phosphoramidite chemistry.

PCR products (15 μl) were digested in 96-well plates. Next, 30 μl of a solution containing 10 mM HEPES [4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid] (pH 7.5), 10 mM MgSO₄, 0.002% (w/v) Triton® X-100, 20 ng/ml of bovine serum albumin, and CEL 1 (Transgenomic®, Inc.; 1:100,000 dilution) was added with mixing on ice, and the plate was incubated at 45° C. for 15 min. The specific activity of the CEL1 was 800 units/μl, where a unit was defined by the manufacturer as the amount of enzyme required to produce 1 ng of acid-soluble material from sheared, heat denatured calf thymus DNA at pH 8.5 in one minute at 37° C. Reactions were stopped by addition of 10 μl of a 2.5 M NaCl solution with 0.5 mg/ml blue dextran and 75 mM EDTA, followed by the addition of 80 μl isopropanol. The reactions were precipitated at 80° C., spun at 4000 rpm for 30 minutes in an Eppendorf Centrifuge 5810. Pellets were resuspended in 8 μl of 33% formamide with 0.017% bromophenol blue dye, heated at 80° C. for 7 minutes and then at 95° C. for 2 minutes. Samples were transferred to a membrane comb using a comb-loading robot (MWG Biotech). The comb was inserted into a slab acrylamide gel (6.5%), electrophoresed for 10 min, and removed. Electrophoresis was continued for 4 h at 1,500-V, 40-W, and 40-mA limits at 50° C.

During electrophoresis, the gel was imaged using a LI-COR® (Lincoln, Nebr.) scanner which was set at a channel capable of detecting the IR Dye 700 and 800 labels. The gel image showed sequence-specific pattern of background bands common to all 96 lanes. Rare events, such as mutations, create new bands that stand out above the background pattern. Plants with bands indicative of mutations of interest were evaluated by TILLING® individual members of a pool mixed with wild type DNA and then sequencing individual PCR products. Plants carrying mutations confirmed by sequencing were grown up as described above (e.g., the M2 plant was backcrossed or outcrossed twice in order to eliminate background mutations and self-pollinated in order to create a plant that was homozygous for the mutation). Mutations identified during TILLING® are shown below in Tables 3 and 4.

TABLE 3 Amino Nucleotide Acid Nucleotide Numbered Numbered Mutation According According Primer EMS According Amino Acid PSSM SIFT to SEQ ID to SEQ ID Gene SEQ IDs. Treatment to SEQ ID Mutation Score Score NO: NO: WAXY  7 and 8 0.75% C791T V168= 3 4 7A WAXY  7 and 8 0.75% C792T R169W 1.00 3 4 7A WAXY  7 and 8 0.75% G794A R169= 3 4 7A WAXY  7 and 8 0.75% G807A E174K 0.07 3 4 7A WAXY  7 and 8 1.00% G825A D180N 0.50 3 4 7A WAXY  7 and 8 0.75% G832A G182D 0.00 3 4 7A WAXY  7 and 8 0.75% C835T T183I 0.19 3 4 7A WAXY  7 and 8 0.75% C851T N188= 3 4 7A WAXY  7 and 8 0.75% C852T Q189* 3 4 7A WAXY  7 and 8 0.75% C858T R191C 31.1 0.00 3 4 7A WAXY  7 and 8 0.75% C860T R191= 3 4 7A WAXY  7 and 8 1.00% C860T R191= 3 4 7A WAXY  7 and 8 0.75% G882A A199T 0.00 3 4 7A WAXY  7 and 8 0.75% G882A A199T 0.00 3 4 7A WAXY  7 and 8 0.75% C911T L208= 3 4 7A WAXY  7 and 8 0.75% C922T P212L 0.00 3 4 7A WAXY  7 and 8 0.75% G947A Intron 3 4 7A WAXY  7 and 8 0.75% G994A Intron 3 4 7A WAXY  7 and 8 0.75% G996A Intron 3 4 7A WAXY  7 and 8 0.75% G1002A Intron 3 4 7A WAXY  7 and 8 0.75% G1002A Intron 3 4 7A WAXY  7 and 8 1.00% C1011T Intron 3 4 7A WAXY  7 and 8 0.75% C1017T Intron 3 4 7A WAXY  7 and 8 0.75% C1017T Intron 3 4 7A WAXY  7 and 8 1.00% C1018T Intron 3 4 7A WAXY  7 and 8 0.75% C1040T Intron 3 4 7A WAXY  7 and 8 0.75% C1045T Intron 3 4 7A WAXY  7 and 8 0.75% C1050T Intron 3 4 7A WAXY  7 and 8 0.75% C1058T Intron 3 4 7A WAXY  7 and 8 1.00% C1060T Intron 3 4 7A WAXY  7 and 8 1.00% C1060T Intron 3 4 7A WAXY  7 and 8 0.75% C1065T Intron 3 4 7A WAXY  7 and 8 1.00% G1070A E220K 14.8 0.00 3 4 7A WAXY  7 and 8 1.00% G1107A G232D 12.1 0.00 3 4 7A WAXY  7 and 8 0.75% C1112T L234= 3 4 7A WAXY  7 and 8 0.75% C1116T A235V 17.9 0.00 3 4 7A WAXY  7 and 8 0.75% C1143T S244F 17.9 0.00 3 4 7A WAXY  7 and 8 0.75% G1202A Intron 3 4 7A WAXY  7 and 8 0.75% C1216T Intron 3 4 7A WAXY  7 and 8 1.00% G1231A Intron 3 4 7A WAXY  7 and 8 0.75% G1235A Intron 3 4 7A WAXY  7 and 8 0.75% C1279T C256= 3 4 7A WAXY  9 and 10 0.75% C1324T F271= 3 4 7A WAXY  9 and 10 0.75% G1394A E295K −7.9 1.00 3 4 7A WAXY  9 and 10 1.00% C1411T N300= 3 4 7A WAXY  9 and 10 0.75% G1425A G305E 29.6 0.00 3 4 7A WAXY  9 and 10 1.00% G1444A K311= 3 4 7A WAXY  9 and 10 1.00% C1459T S316= 3 4 7A WAXY  9 and 10 1.00% G1533A G341E 17.6 0.01 3 4 7A WAXY  9 and 10 0.75% G1542A G344D 16.0 0.00 3 4 7A WAXY  9 and 10 1.00% G1542A G344D 16.0 0.00 3 4 7A WAXY  9 and 10 0.75% C1561T D350= 3 4 7A WAXY  9 and 10 0.75% G1566A S352N 8.4 0.14 3 4 7A WAXY  9 and 10 0.75% G1585A K358= 3 4 7A WAXY  9 and 10 0.75% G1586A D359N 28.9 0.00 3 4 7A WAXY  9 and 10 0.75% C1595T L362F 20.6 0.00 3 4 7A WAXY  9 and 10 0.75% C1599T T363I 13.7 0.15 3 4 7A WAXY  9 and 10 0.75% C1638T Intron 3 4 7A WAXY  9 and 10 0.75% C1638T Intron 3 4 7A WAXY  9 and 10 0.75% G1647A Intron 3 4 7A WAXY  9 and 10 0.75% C1656T Intron 3 4 7A WAXY  9 and 10 1.00% G1668A Intron 3 4 7A WAXY  9 and 10 0.75% C1693T Intron 3 4 7A WAXY  9 and 10 0.75% G1706A Intron 3 4 7A WAXY  9 and 10 0.75% G1706A Intron 3 4 7A WAXY  9 and 10 0.75% C1736T N378= 3 4 7A WAXY  9 and 10 0.75% C1736T N378= 3 4 7A WAXY  9 and 10 0.75% G1761A G387R 12.0 0.01 3 4 7A WAXY  9 and 10 1.00% G1770A V390M 15.6 0.00 3 4 7A WAXY  9 and 10 1.00% G1778A R392= 3 4 7A WAXY  9 and 10 0.75% G1808A R402= 3 4 7A WAXY  9 and 10 0.75% C1809T L403= 3 4 7A WAXY  9 and 10 0.75% G1814A E404= 3 4 7A WAXY  9 and 10 0.75% G1823A K407= 3 4 7A WAXY  9 and 10 0.75% G1823A K407= 3 4 7A WAXY  9 and 10 0.75% C1851T P417S 12.8 0.12 3 4 7A WAXY  9 and 10 0.75% G1868A E422= 3 4 7A WAXY  9 and 10 0.75% G1868A E422= 3 4 7A WAXY  9 and 10 0.75% C1890T L430= 3 4 7A WAXY  9 and 10 0.75% C1907T Intron 3 4 7A WAXY  9 and 10 0.75% G1951A Intron 3 4 7A WAXY  9 and 10 1.00% G1960A Intron 3 4 7A WAXY 11 and 0.75% C1990T G431= 3 4 7A 12 WAXY 11 and 0.75% G1995A G433E 0.00 3 4 7A 12 WAXY 11 and 1.00% C2042T P449S 18.4 0.05 3 4 7A 12 WAXY 11 and 0.75% G2060A V455M 20.1 0.05 3 4 7A 12 WAXY 11 and 0.75% C2100T A468V 16.4 0.00 3 4 7A 12 WAXY 11 and 0.75% G2103A G469D 28.6 0.00 3 4 7A 12 WAXY 11 and 0.75% C2122T V475= 3 4 7A 12 WAXY 11 and 0.75% C2134T F479= 3 4 7A 12 WAXY 11 and 1.00% C2152T I485= 3 4 7A 12 WAXY 11 and 0.75% C2152T I485= 3 4 7A 12 WAXY 11 and 0.75% G2155A Q486= 3 4 7A 12 WAXY 11 and 0.75% G2180A Splice 3 4 7A 12 WAXY 11 and 1.00% G2180A Splice 3 4 7A 12 WAXY 11 and 0.75% G2199A Intron 3 4 7A 12 WAXY 11 and 0.75% C2224T Intron 3 4 7A 12 WAXY 11 and 0.75% C2255T Intron 3 4 7A 12 WAXY 11 and 0.75% G2274A C496Y 32.7 0.03 3 4 7A 12 WAXY 11 and 0.75% C2283T A499V 22.0 0.09 3 4 7A 12 WAXY 11 and 0.75% G2284A A499= 3 4 7A 12 WAXY 11 and 0.75% G2292A G502D 19.2 0.00 3 4 7A 12 WAXY 11 and 1.00% G2315A E510K 0.01 3 4 7A 12 WAXY 11 and 0.75% G2329A G514= 3 4 7A 12 WAXY 11 and 0.75% C2393T Intron 3 4 7A 12 WAXY 11 and 0.75% G2449A Intron 3 4 7A 12 WAXY 13 and 1.00% C783T Intron 5 6 7D 14 WAXY 13 and 0.75% G785A Intron 5 6 7D 14 WAXY 13 and 1.00% G785A Intron 5 6 7D 14 WAXY 13 and 0.75% G835A G178= 5 6 7D 14 WAXY 13 and 0.75% G851A D184N 0.15 5 6 7D 14 WAXY 13 and 1.00% G851A D184N 0.15 5 6 7D 14 WAXY 13 and 1.00% G860T D187Y 31.4 0.00 5 6 7D 14 WAXY 13 and 0.75% G879A S193N 18.6 0.04 5 6 7D 14 WAXY 13 and 1.00% C884T L195F 0.3 0.41 5 6 7D 14 WAXY 13 and 0.75% C890T Q197* 5 6 7D 14 WAXY 13 and 1.00% G896A A199T 0.00 5 6 7D 14 WAXY 13 and 1.00% G957A Splice 5 6 7D 14 WAXY 13 and 1.00% C964T Intron 5 6 7D 14 WAXY 13 and 1.00% C964T Intron 5 6 7D 14 WAXY 13 and 1.00% C992T Intron 5 6 7D 14 WAXY 13 and 1.00% G1026A Intron 5 6 7D 14 WAXY 13 and 1.00% G1026A Intron 5 6 7D 14 WAXY 13 and 0.75% C1055T Intron 5 6 7D 14 WAXY 13 and 0.75% C1099T Intron 5 6 7D 14 WAXY 13 and 0.75% G1108A Splice 5 6 7D 14 WAXY 13 and 1.00% G1109A G219E 0.00 5 6 7D 14 WAXY 13 and 0.75% G1130A C226Y 18.0 0.00 5 6 7D 14 WAXY 13 and 0.75% G1147A G232S 9.2 0.00 5 6 7D 14 WAXY 13 and 1.00% G1148A G232D 12.0 0.00 5 6 7D 14 WAXY 13 and 0.75% G1160A C236Y 30.6 0.00 5 6 7D 14 WAXY 13 and 0.75% C1161T C236= 5 6 7D 14 WAXY 13 and 0.75% G1170A K239= 5 6 7D 14 WAXY 13 and 0.75% C1184T S244F 17.8 0.00 5 6 7D 14 WAXY 13 and 0.75% C1185T S244= 5 6 7D 14 WAXY 13 and 0.75% G1200A R249= 5 6 7D 14 WAXY 13 and 0.75% C1222T Intron 5 6 7D 14 WAXY 13 and 0.75% C1244T Intron 5 6 7D 14 WAXY 13 and 1.00% C1244T Intron 5 6 7D 14 WAXY 13 and 1.00% C1266T Intron 5 6 7D 14 WAXY 13 and 1.00% G1269A Intron 5 6 7D 14 WAXY 13 and 0.75% C1279T Intron 5 6 7D 14 WAXY 15 and 0.75% G1313A Intron 5 6 7D 16 WAXY 15 and 0.75% C1348T Intron 5 6 7D 16 WAXY 15 and 1.00% G1351A V253M 19.3 0.01 5 6 7D 16 WAXY 15 and 0.75% C1404T D270= 5 6 7D 16 WAXY 15 and 0.75% C1419T N275= 5 6 7D 16 WAXY 15 and 0.75% C1424T P277L 0.00 5 6 7D 16 WAXY 15 and 0.75% G1430A R279K 0.23 5 6 7D 16 WAXY 15 and 1.00% G1430A R279K 0.23 5 6 7D 16 WAXY 15 and 0.75% G1477A E295K −6.8 1.00 5 6 7D 16 WAXY 15 and 0.75% G1488A K298= 5 6 7D 16 WAXY 15 and 0.75% C1491T I299= 5 6 7D 16 WAXY 15 and 0.75% C1494T N300= 5 6 7D 16 WAXY 15 and 0.75% G1507A G305R 29.6 0.00 5 6 7D 16 WAXY 15 and 0.75% G1509A G305= 5 6 7D 16 WAXY 15 and 0.75% G1518A Q308= 5 6 7D 16 WAXY 15 and 0.75% G1528A V312M 0.00 5 6 7D 16 WAXY 15 and 0.75% C1535T T314M 25.8 0.00 5 6 7D 16 WAXY 15 and 0.75% C1545T P317= 5 6 7D 16 WAXY 15 and 0.75% G1557A E321= 5 6 7D 16 WAXY 15 and 0.75% G1558A E322K 29.0 0.00 5 6 7D 16 WAXY 15 and 0.75% G1558A E322K 29.0 0.00 5 6 7D 16 WAXY 15 and 1.00% C1566T I324= 5 6 7D 16 WAXY 15 and 1.00% C1566T I324= 5 6 7D 16 WAXY 15 and 0.75% G1571A G326D 7.8 0.11 5 6 7D 16 WAXY 15 and 0.75% C1608T R338= 5 6 7D 16 WAXY 15 and 0.75% C1608T R338= 5 6 7D 16 WAXY 15 and 0.75% C1608T R338= 5 6 7D 16 WAXY 15 and 0.75% C1622T T343I 13.7 0.05 5 6 7D 16 WAXY 15 and 1.00% C1623T T343= 5 6 7D 16 WAXY 15 and 0.75% G1625A G344D 16.0 0.00 5 6 7D 16 WAXY 15 and 0.75% C1629T I345= 5 6 7D 16 WAXY 15 and 0.75% G1630A V346I 10.4 0.04 5 6 7D 16 WAXY 15 and 0.75% C1659T D355= 5 6 7D 16 WAXY 15 and 0.75% C1661 P356L 20.9 0.00 5 6 7D 16 WAXY 15 and 0.75% C1682T A363V 12.5 0.21 5 6 7D 16 WAXY 15 and 0.75% C1682T A363V 12.5 0.21 5 6 7D 16 WAXY 15 and 0.75% C1713T Intron 5 6 7D 16 WAXY 15 and 0.75% C1736T Intron 5 6 7D 16 WAXY 15 and 1.00% C1736T Intron 5 6 7D 16 WAXY 15 and 0.75% T1737G Intron 5 6 7D 16 WAXY 15 and 0.75% C1749T Intron 5 6 7D 16 WAXY 15 and 0.75% G1758A Intron 5 6 7D 16 WAXY 15 and 0.75% C1774T Intron 5 6 7D 16 WAXY 15 and 1.00% C1774T Intron 5 6 7D 16 WAXY 15 and 0.75% G1840A G387= 5 6 7D 16 WAXY 15 and 0.75% G1843A L388= 5 6 7D 16 WAXY 15 and 1.00% C1844T P389S 16.3 0.01 5 6 7D 16 WAXY 15 and 0.75% C1865T L396= 5 6 7D 16 WAXY 15 and 0.75% G1897A Q406= 5 6 7D 16 WAXY 15 and 0.75% C1905T P409L 13.7 0.13 5 6 7D 16 WAXY 15 and 1.00% C1905T P409L 13.7 0.13 5 6 7D 16 WAXY 15 and 0.75% G1907A D410N 13.5 0.00 5 6 7D 16 WAXY 15 and 0.75% C1918T I413= 5 6 7D 16 WAXY 15 and 0.75% G1970A Splice 5 6 7D 16

TABLE 4 Nucleotide Amino Acid Nucleotide Numbered Numbered Primer Mutation Amino According According SEQ ID EMS According to Acid PSSM SIFT to SEQ ID to SEQ ID Gene NOs. Treatment SEQ ID Mutation Score Score NO: NO: WAXY  7 and 8 0.075% G789A V168I 0.00 3 4 7A WAXY  7 and 8 0.075% G794A R169= 3 4 7A WAXY  7 and 8 0.075% C802T T172I 0.06 3 4 7A WAXY  7 and 8 0.075% G812A K175= 3 4 7A WAXY  7 and 8 0.075% C860T R191= 3 4 7A WAXY  7 and 8 0.075% C860T R191= 3 4 7A WAXY  7 and 8 0.075% G899A R204= 3 4 7A WAXY  7 and 8 0.075% G899A R204= 3 4 7A WAXY  7 and 8 0.075% C1050T Intron 3 4 7A WAXY  7 and 8 0.075% G1057A Intron 3 4 7A WAXY  7 and 8 0.075% G1069A G219= 3 4 7A WAXY  7 and 8 0.075% C1181T Intron 3 4 7A WAXY  7 and 8 0.075% C1196T Intron 3 4 7A WAXY  7 and 8 0.075% G1228A Intron 3 4 7A WAXY  9 and 10 0.075% G1394A E295K −7.9 1.00 3 4 7A WAXY  9 and 10 0.075% C1402T R297= 3 4 7A WAXY  9 and 10 0.075% G1435A Q308= 3 4 7A WAXY  9 and 10 0.075% G1469A A320T 21.5 0.01 3 4 7A WAXY  9 and 10 0.075% C1485T S325F 25.4 0.00 3 4 7A WAXY  9 and 10 0.075% G1490A E327K 18.7 0.11 3 4 7A WAXY  9 and 10 0.075% G1522A M337I 1.1 1.00 3 4 7A WAXY  9 and 10 0.075% G1572A W354* 3 4 7A WAXY  9 and 10 0.075% C1633T Intron 3 4 7A WAXY  9 and 10 0.075% C1638T Intron 3 4 7A WAXY  9 and 10 0.075% G1647A Intron 3 4 7A WAXY  9 and 10 0.075% G1721A E373= 3 4 7A WAXY  9 and 10 0.075% G1897A Intron 3 4 7A WAXY  9 and 10 0.075% C1918T Intron 3 4 7A WAXY 11 and 0.075% G2017A L440= 3 4 7A 12 WAXY 11 and 0.075% C2042T P449S 18.4 0.05 3 4 7A 12 WAXY 11 and 0.075% C2129T R478C 34.2 0.00 3 4 7A 12 WAXY 11 and 0.075% G2162A G489R 25.3 0.00 3 4 7A 12 WAXY 11 and 0.075% G2406A Intron 3 4 7A 12 WAXY 19 and 0.075% G1115A V224M 12.2 0.00 1 2 4A 20 WAXY 19 and 0.075% C1140T T232M 17.8 0.00 1 2 4A 20 WAXY 19 and 0.075% C1171T N242= 1 2 4A 20 WAXY 19 and 0.075% C1236T Intron 1 2 4A 20 WAXY 19 and 0.075% C1265T Intron 1 2 4A 20 WAXY 19 and 0.075% G1405A G297= 1 2 4A 20 WAXY 19 and 0.075% G1504A R330= 1 2 4A 20 WAXY 19 and 0.075% G1607A A365T −0.1 0.17 1 2 4A 20 WAXY 17 and 0.075% C1983T Intron 1 2 4A 18 WAXY 17 and 0.075% G1993A G434E 33.7 0.00 1 2 4A 18 WAXY 17 and 0.075% C2040T P450S 18.7 0.06 1 2 4A 18 WAXY 17 and 0.075% C2040T P450S 18.7 0.06 1 2 4A 18 WAXY 17 and 0.075% G2053A R454K 11.8 0.09 1 2 4A 18 WAXY 17 and 0.075% C2057T A455= 1 2 4A 18 WAXY 17 and 0.075% C2120T V476= 1 2 4A 18 WAXY 17 and 0.075% C2154T L488F 24.1 0.00 1 2 4A 18 WAXY 17 and 0.075% G2161A G490E 25.6 0.00 1 2 4A 18

Phenotypic Analysis

Phenotype was examined in M3 progeny of an Express line carrying mutations that were predicted by bioinformatics analysis to affect gene function. The mutations were a truncation mutation in Wx-7D (Q197*) which was predicted to result in premature termination of the protein and a missense mutation in the Wx-7A homoeolog (A468V) which was predicted to severely affect protein function by a SIFT score of 0.00 and a change in PSSM score of 16.4. Since the Express line lacks the Wx-4A homoeolog, progeny that were homozygous for both mutations were predicted to display nearly a full waxy phenotype. Iodine was used to stain the endosperm of the progeny. Waxy endosperm stains a reddish brown with iodine, whereas amylose-containing endosperm stains very dark blue (Nakamura et al., Mol. Gen. Genet. 248: 253-259, 1995). Seeds were soaked in water for three hours, cut in half, and then treated with a four-fold dilution of iodine stain for 15 minutes. In contrast to seeds of the parental Express line that stained very dark blue, seeds of the double homozygous mutant stained very light blue with iodine indicating that amylose levels were significantly reduced by the mutations. These findings are consistent with the effect on protein function predicted by the mutations' SIFT and POSSUM scores.

Deposit Information

If deemed necessary by the Commissioner of Patents and Trademarks or any persons acting on his behalf, Applicants will make a deposit of at least 2500 seeds for each of the wheat varieties containing an exemplary mutation described in this application with the American Type Culture Collection (ATCC). The seeds deposited with the ATCC will be taken from the deposit maintained by Anawah Inc., 1102 Columbia Street, Suite 600, Seattle, Wash., 98104, since prior to the filing date of this application. Access to this deposit will be available during the pendency of the application to the Commissioner of Patents and Trademarks and persons determined by the Commissioner to be entitled thereto upon request. Upon allowance of any claims in the application and if designated by the Commissioner of Patents and Trademarks as a condition for allowance of those claims, Applicants will make the deposit available to the public pursuant to 37 CFR 1.808. All deposits related to this application will be maintained in the ATCC depository, which is a public depository, for a period of 30 years, or 5 years after the most recent request, or for the enforceable life of the patent, whichever is longer, and will be replaced if it becomes nonviable during that period. Additionally, Applicants have or will satisfy all requirements of 37 CFR Sections 1.801-1.809, including providing an indication of the viability of the sample upon deposit. Applicants have no authority to waive any restrictions imposed by law o the transfer of biological material or its transportation in commerce. Applicants do not waive any infringement of their rights granted under this patent or under the Plant Variety Protection Act (7 USC 2321 et seq.).

The above examples are provided to illustrate the invention but not limit its scope. Other variants of the invention will be readily apparent to one of ordinary skill in the art and are encompassed by the appended claims and all their equivalents. All publications, patents, and patent applications cited herein are hereby incorporated by reference. 

We claim:
 1. A method of producing a tetraploid or hexaploid wheat plant, or part thereof, exhibiting reduced waxy enzyme activity compared to a wild type wheat plant or part thereof, said method comprising the steps of: a) obtaining plant material from a parent wheat plant, wherein the parent wheat plant comprises two or more wild-type waxy genes; b) creating mutagenized plant material by inducing at least one mutation in each of the at least two waxy genes of the parent plant material, wherein said mutations are induced by treating the wheat plant material with a mutagen; c) analyzing the mutagenized wheat plant material, or a progeny wheat plant produced from the mutagenized wheat plant material, to identify a plant having at least one mutation in each of the at least two waxy genes, wherein said analysis is performed by isolating genomic DNA from the mutagenized wheat plant material, or a progeny wheat plant produced from the mutagenized wheat plant material, and amplifying segments of a waxy gene in the isolated genomic DNA by using primers specific to the waxy gene or to the DNA sequences adjacent to the waxy gene, wherein one of the at least two mutated waxy genes being identified encodes a protein comprising a A468V mutation in SEQ ID NO: 4, and one of the at least two mutated waxy genes being identified encodes a protein comprising a Q197* truncation mutation in SEQ ID NO: 6; and d) producing a tetraploid or hexaploid progeny wheat plant from the mutagenized wheat plant material or the progeny wheat plant produced from the mutagenized wheat plant material, each comprising the at least two mutated waxy genes as identified in step c), wherein the A468V mutation in SEQ ID NO: 4 and the Q197* truncation mutation in SEQ ID NO: 6 cause a reduction waxy enzyme activity in the progeny wheat plant compared to the parent wheat plant of step a), as indicated by a reduced level of amylose in the progeny wheat plant or a part thereof.
 2. The method of claim 1 wherein the wheat plant material is selected from the group consisting of seeds, pollen, plant cells, and plant tissue.
 3. The method of claim 1 wherein the mutagen is ethyl methanesulfonate.
 4. The method of claim 3 wherein the concentration of ethyl methanesulfonate used is from about 0.75% to about 1.2%.
 5. The method of claim 1 wherein analyzing the mutagenized plant material or a progeny wheat plant produced from the mutagenized wheat plant material further comprises analysis of a starch characteristic.
 6. The method of claim 5 wherein the analysis of a starch characteristic comprises iodine staining.
 7. The method of claim 1 wherein the part thereof is a seed. 